DE4013061A1 - DEVICE FOR FLUIDIZING POWDER IN A CONTAINER AND EXHAUSTING FLUIDIZED POWDER DIRECTLY TO A SPRAY GUN OF AN ELECTROSTATIC POWDER COATING SYSTEM - Google Patents

Description

The invention relates to a device for fluidizing fluidized in a container and discharge fluidized powder directly to a spray gun of an electro static powder coating system according to the generic term of claim 1. Such a device is from the German utility model G 88 04 951 known.

With the known device mentioned, the powder can un indirectly from the original container, i.e. without the requirement an intermediate container, and the spray gun are fed. Practice has now shown that this Device then works properly when the powder is flawless, d. i.e., no lumps, no foreign particles and none the given average grain size essential  exceeding powder particles. Now it can occur that the powder in the original container for example by over-long storage or by tempera influences, is mixed with powder lumps, or even Contains particles of excessive grain size. This then leads to an uneven coating of the workpiece, which ins is particularly quality-reducing if it is a Top coating (finish coating) is concerned. Even bigger is the risk of undesirable clumping if the device picks up powder from a container which has already been sprayed, i.e. returned during recycling obtained powder. In the suction and leading to the spray gun Delivery line a filter of required fineness use, be it at the suction opening or at any elsewhere on the line, this problem cannot solve because such a filter, as practice has shown clogged after a very short time. This has to be taken into account see that with these devices only with one very low suction is worked and an increase the intake to keep a filter free of the powder from the fluid bed would significantly interfere. The installation of an intermediate chamber with screening machine in the Ab Suction and delivery line would be possible, but would have to the powder that has fallen through the sieve of the sieving machine inflated again and transported on. In order to would be the great advantage of immediate admission and support change of powder from the transport container to the spray gun get lost with its low construction.

The object of the present invention is therefore the one direction of the type mentioned to improve so that while maintaining their constructive simplicity and their Mobility ensures that there is no powder to the spray gun lumps and / or oversized particles. The solution this task arises from the characteristic features of claim 1.  

Through the sieve basket surrounding the suction opening at a distance, who dives into the sieve bed created around him comes as experiments have shown, even then it does not ver darning of the sieve if it is very fine-meshed. The reason for this is to be seen in the fact that outside Screening powder particles through the fluidizing air immediately be moved away again, i.e. do not stick to the sieve wires and slowly clog the sieve.

Particularly expedient embodiments of the invention are shown in marked the subclaims.

Embodiments of the invention are shown in the drawing shown for example. Show it:

Fig. Tikalschnitt 1, a first embodiment in comparison, with a single suction and delivery line,

Fig. 2 is a view according to Fig. 1 From a versatile form,

Fig. 2A is a view of FIG. 2 in verklei nerten scale with additional Dar position of the powder container,

Fig. 3 is a view according to Fig. 1 of a modification form,

Fig. 4 is a view according to Fig. 2 form a conversion Ab,

Fig. 5 shows a second embodiment with two suction and delivery lines in vertical section,

Fig. 6 is a view according to Fig. 5 a modification form,

Fig. 7 is a view according to Fig. 5 a modification form,

Fig. 8 is a view of FIG. 5 from a conversion form and

Fig. 9 shows a third embodiment with six suction and delivery lines in the vertical section.

The embodiment of Fig. 1 has a single vertical suction and delivery line 10 which forms a suction opening 10 a at its lowermost end. At its upper end, the line 10 is held in a plate 11 , which can be, for example, the arm of a - not shown - vertical Hubvor direction. A further line, preferably a hose line, leads directly from the upper end of the pipe end 10 to a conventional powder spray gun. On the tube 10 , a bell body 12 open at the bottom is attached, which carries on its outside a plurality of vertical compressed air tubes 13 , which are connected at their upper ends via a hose line, also not shown, to a compressed air source and at their lower end carry fluidizing rings 14 with compressed air outlet openings 14 a. Of course, it is sufficient if one of the tubes 13 carries compressed air, while the other tubes 13 only serve to support the fluidizing ring 14 . Another possibility is to connect the upper ends of the tubes 13 by means of an annular tube, which in turn is then connected to the compressed air source.

On the pipeline 10 , a substantially cylindrical strainer basket 15 is attached, which surrounds the lower region of the pipeline 10 , including the suction opening 10 a, at a distance, its lower end face 15 a being formed as a flat cone pointing downward. It is essential that the fluidizing openings 14 a are located outside the screen basket 15 , to the side of it at a level directly below that of the lowest point (cone tip) of the screen basket 15 .

Fig. 2 shows a modification of the device of Fig. 1. The modification consists on the one hand in that the strainer basket 15 ( Fig. 2) has a much larger diameter and thus the interior than that of Fig. 1. Here is the strainer basket 15 attached to the bell 12 here. The Blasluftöff openings 14 a are at the level of the lowest point (cone tip) of the suction and delivery pipe 10 below the outer region of the strainer 15 , as can be clearly seen from the drawing. This comparatively large screen basket 15 is particularly suitable for the case, as will be explained later, that the screen basket should be very fine-meshed. The further modification compared to the embodiment of FIG. 1 is that a vibra gate 16 is flanged to the tube 10 above the bell 12 , in which case the holding plate 11 is connected via a vibration-damping buffer 17 to a second holding plate 18 . In this case, the second holding plate 18 is connected to the support arm of a lifting device, not shown, or represents this.

The operation of the device described with reference to FIGS . 1 and 2 will now be explained with reference to FIG. 2A. In this case, 20 denotes a powder container which is open at the top and is filled with powder 21 . Furthermore, a vibrator 22 is attached to the outside of the container 20 and the container stands on vibration-damping feet 23 . For fluidizing and conveying the powder 21 directly to a powder spray gun, the unit consisting essentially of suction line 10 , fluidizing rings 14 , strainer basket 15 and vibrator 16 is introduced into the powder 21 from above. Consisting of the blowing openings 14 a of the Fluidisierringe 14 exiting compressed air causes a spatially limited (partial) Fluidisie tion of the powder 21 to the submerged portion of the unit around, in which case fluidized powder to flow through the strainer basket 15 therethrough to the suction port 10 a, and within the tube 10 is led upwards. The immersion of the sieve 15 in the powder mass and the permeability of the sieve are supported in that the vibrator 16 excites the sieve basket 15 to vibrate. The supply of not yet fluidized powder, in particular from the lateral edge area (crater edge), to the fluidization area is supported by the vibrator 22 causing the powder mass 21 to vibrate. With advancing powder suction, the unit he mentioned is lowered ever lower in the container 20 .

The details of the method of operation and the advantages of the unit consisting of intake and delivery line 10 , compressed air line 13 and fluidizing rings 14 are not necessary because, as mentioned at the beginning, this unit is already known. The screen basket 15 according to the invention can be said that this must enclose the lower region of the tube 10 and the suction openings 10 a at a distance, because only in this way a blockage of the screen fabric is avoided. The finer the screen mesh, the larger the screen basket must be; so at a medium-fine sieve can with a Siebkorbgröße shown in FIG. 1 out come, whereas at very fine screens, a basket according to FIG. 2 is preferable. Furthermore, the position of the blown air openings 14 a of the fluidizing rings 14 relative to the basket 15 is important. The blown air openings 14 a must not be located within half of the screen basket 15 , but must be outside the same, at a height equal to that of the lowest point of the screen basket or immediately below.

In a screen basket 15 with a comparatively small diameter, that is, a screen basket according to FIG. 1, the blowing air openings 14 a can be arranged to the side of the screen basket; If, on the other hand, the strainer basket has a considerable diameter, as shown in FIG. 2, then an arrangement according to FIG. 2 is preferable, because with an exclusively since arrangement of the blown air openings there could be insufficient powder fluidization under the suction opening 10 a. With sufficient dimensioning of the strainer basket 15 and the above-mentioned arrangements of the fluidizing rings relative to the strainer basket there is no danger that the strainer basket will become blocked after a shorter or longer period of operation. However, in order to make it easier for the sieve basket to penetrate the powder, it can be advantageous to let the sieve 15 vibrate, for example by means of the vibrator 16 from FIG is, so has no particular preferred direction. In this way, security against screen blockages is additionally increased. The further vibrator 22 shown in FIG. 2A for excitation of the container powder body is known per se and serves to collapse the lateral powder crater edges resulting during operation, so to speak; in other words, the powder of the edge zones should be fed to the fluidizing area. Extensive tests have now shown the following. If the powder mass is set into vibration on all sides by the vibrator 22 , as is desired when the screen basket 15 vibrates, then there is a risk of the powder mass separating and / or solidifying. The reason for this is the vertical vibrations. It is therefore preferable that the vibrator 22 excites the powder 21 only to horizon tal vibrations; as a result, the powder of the edge zones is fed to the fluidizing region, without, however, solidification or segregation occurring. Furthermore, it has been found that when both the screen basket 15 vibrates and the powder mass vibrates due to the vibrators 16 and 22 , it is expedient to avoid interference if the screen basket and powder mass vibrate or oscillate with different frequencies. For example, the powder mass could vibrate at 50 Hz, i.e. the mains frequency, and the sieve basket 15 could vibrate at 100 Hz. For the structural attachment of the vibrators 16 , 22, there are several possibilities. Thus, as shown in FIG. 2, the vibrator 16 can be attached to the tube 10 , which means that the entire unit 10 , 13 , 14 , 15 then vibrates. However, it is also possible to let only the strainer basket 15 vibrate, in which case the vibrator 16 is attached to the strainer basket and the strainer basket is fastened to the tube 10 via vibration dampers. The vibrator 22 can be attached directly to the container 20 , but also on a receptacle in which the container 20 is inserted, or on a vibrating table on which the container 20 is placed.

FIGS. 3 and 4 show another design of the strainer basket 15 °. The strainer basket 15 of FIG. 3 has the shape of a flat cylinder with a conical bottom and top surface. This screen basket penetrates particularly well into the powder masses. The screen basket 15 of FIG. 4 is characterized by a particularly large surface; it is constructed from a plurality of “fins”, which, however, are connected to one another at the base of the fin (around the tube 10 ), the external shape being roughly comparable to that of a fin cooler. The sieve holder shown at 30 consists only of struts, so that the passage mentioned in the area around the tube 10 is guaranteed.

Basically, it can be said about the shape and size of the screen basket that the screen net - as already mentioned above - the finer the surface of the screen basket 15 , the finer it can be.

Large surface shapes, such as the shape of the strainer basket of Fig. 4, are therefore very convenient. On the other hand, the strainer basket 15 should at least not be too large if the device is used for conveying from comparatively small containers. Appropriate considerations are therefore necessary here.

It often happens that not only one suction and delivery pipe 10 but two such pipes in tandem arrangement are provided for feeding two powder spray guns in the devices of the type of interest here. Of course you could now attach a separate screen basket to each of these pipes, but this has proven to be of little use, especially if the two suction and delivery pipes are only a short distance apart. Figs. 5 to 8 now show devices with two intake and delivery pipes 10 arranged in tandem and the common sieve basket 15 °. The screen basket 15 of FIG. 5 corresponds approximately to that of FIG. 1, that of FIG. 6 to that of FIG. 2, that of FIG. 7 to that of FIG. 3 and finally that of FIG. 8 to that of FIG. 4 ; the drawings obviously understand themselves, so that special explanations are not required.

Finally, FIG. 9 shows a device with six suction and delivery tubes 10 , which are enclosed by a common screen basket 15 . Due to the relatively large diameter of the strainer basket 15 , particular attention should be paid to a suitable arrangement of the fluidizing rings 14 or the blown air openings 14 a, additional baffles 40 being able to be provided to produce a uniform fluid bed and a uniform removal of the powder through the six tubes 10 . The arrangement of the tubes 10 can take place in a row, as shown in FIG. 9, the screen basket 15 then being given an adapted, elongated elliptical cross section, or else the tubes 10 are arranged in the manner of a bundle, in which case the Basket 15 can be circular cylindrical. An arrangement as shown in Fig. 9 is particularly suitable for feeding coating booths with a larger number of spray guns.

Of course, the invention is not limited to the embodiments shown, but they are possible against numerous other modifications, as has already been emphasized with regard to the shape, size and arrangement of the strainer basket and the arrangement of the vibrators. But it is also not necessary that the suction and delivery line 10 , fluidizing device 13 , 14 , 14 a and screen basket 15 constitute an integral unit; it is possible, for example, to insert sieve basket 15 and fluidizing device 13 , 14 , 14 a as a unit in advance into the powder mass and only then to separate pipe 10, which is separate from this unit.

With the invention, the guarantee is created that the abge conveyed powder free of lumps and free of oversized particles is, although there are no disruptions to funding due to sieve basket clogging comes when with very fine sieves and / or worked with little fluidizing air and / or with little suction becomes.

Claims (11)

1. Device for fluidizing powder in a container and discharging fluidized powder un directly to a spray gun of an electrostatic powder coating system, with a suction and delivery line immersed in the container from above and a pressure line also immersing into the container from above , which have blow openings for producing a spatially limited powder fluid bed, characterized in that the area of the suction line ( 10 ), including its suction opening ( 10 a), which is immersed in the powder fluid bed, is enclosed at a distance from a sieve basket ( 15 ) and that the blowing openings ( 14 a) of the compressed air line ( 13 ) are since Lich outside the screen basket ( 15 ) and / or below the same. 2. Device according to claim 1, characterized by a vibrator ( 16 ) for vibrating the screen basket ( 15 ). 3. Device according to claim 1 or 2, characterized in that the screen basket ( 15 ) on the suction and Förderlei device ( 10 ) is attached. 4. Device according to claim 3, characterized in that the suction and delivery line ( 10 ), fluidizing device ( 13 , 14 , 14 a) and screen basket ( 15 ) are integrated into one unit. 5. Device according to one of claims 1 to 4, characterized in that the screen basket ( 15 ) has the shape of a cylinder with a conical bottom surface, the tip ( 15 a) facing downwards. 6. Device according to one of claims 1 to 5, characterized in that the strainer basket ( 15 ) has a zer fissured surface, preferably in the manner of ribs. 7. Device according to one of claims 1 to 6, characterized in that the screen basket volume in reverse return ratio to the fineness of the sieve. 8. Device according to one of claims 1 to 7, characterized by vibration-damping connecting element ( 17 ). 9. A device with a plurality of mutually parallel suction and delivery lines according to one of claims 1 to 8, characterized in that a common, all suction and delivery lines ( 10 ) enclosing sieve basket ( 15 ) is seen before. 10. Device according to one of claims 1 to 9, characterized by a vibrator ( 22 ) for setting the powder mass in horizontal vibrations. 11. The device according to claim 10, characterized in that the driven by the first vibrator ( 16 ) sieve basket ( 15 ) vibrates in a different frequency than the oscillation frequency of the second vibrator ( 22 ) driven powder mass.